Tele-diagnostic device

ABSTRACT

A system ( 10 ) for collecting a plurality of diagnostic information and transmitting the diagnostic information to a remote location. The system ( 10 ) comprises a glove member ( 12 ) adaptable to be worn on a person&#39;s hand and an interface unit ( 20 ) in electrical communication with the glove member ( 12 ). The interface unit ( 20 ) is capable of transmitting information to, and receiving information from, a remote location. The glove member ( 12 ) comprises a palm portion ( 1 ), a wrist portion ( 3 ) and five phalange portions ( 5-13 ). The glove member ( 12 ) further comprises an EKG diagnostic device, a blood pressure and pulse rate diagnostic device ( 54 ) and a temperature device ( 64 ). The glove member ( 12 ) may also further comprise a %O 2  diagnostic device ( 70 ) and an auscultation device ( 80 ).

TECHNICAL FIELD

1. This invention relates to a system, and a probe for use with the system, for obtaining a plurality of medical diagnostic information. In particular, the present invention relates to a system and probe for use with the system, for gathering cardiac-related diagnostic information and transmitting the information to a remote location, such as a medical monitoring command center.

BACKGROUND

2. Doctor-patient relationships are as old as human civilization itself. Over the centuries this relationship has undergone, surprisingly enough, very little change. One way or another the patient and the doctor came into contact with each other in person. This process was called a patient visit or doctor visit, as the case may be. From the very beginning of this patient-doctor interaction, a certain format and structure evolved and later this was laid down as a stipulated discipline in the practice of medicine. The doctor interrogates the patient in a methodical way, the patient provides the answers, which in fact, is the history of the evolution of the patient's illness. The doctor then examines the patient, makes crucial observations and gathers diagnostic data, or information, which are the fingerprints of the illness the patient is suffering from. An intellectual process ensues in the doctor's mind, where he correlates the history of the illness with the diagnostic information he gathered and the conclusion he arrives at, essentially, is the diagnosis of the patient's malady.

3. Over the years, innovations like the telegraph, the telephone, fax machines and of late, the e-mail and the Internet, has enhanced the patient-doctor relationship quite substantially. These innovations have curtailed the need for more frequent personal visits, by the patient or the doctor, as the case may be. Doctors on their part however, always prefer to speak to the patient and gather vital diagnostic information personally by themselves, even when the patient is located remotely from the doctor. Thus, it would be desirable to be able to gather and transmit a plurality of diagnostic information and converse with a doctor, or medical professional, at a remote location. Moreover, it would be desirable to provide a single apparatus which could collect a plurality of diagnostic information.

4. Moreover, it has been observed that at least about one third of the patients who visit emergency rooms (ER) across the country, do not have emergency problems. They visit the ER because they believed that they are having a heart attack or another medical emergency, or they prefer to use the emergency room instead of paying a visit to their general practitioner (GP) or primary care physician (PCP). These unnecessary visits to the ER sometimes prove to be quite costly to the patients and/or their healthcare underwriter in more ways than one. As a first example, if someone had epigastric pain from indigestion, a visit to the GP or PCP would cost, at the most about $75.00. A visit to any ER for the same purpose could cost upwards of about $500. Also, while medical professionals tend to a patient not actually requiring emergency treatment, another patient who actually could benefit from emergency treatment may go untreated. If the patient has been provided with a means for gathering and transmitting a plurality of diagnostic information and for conversing with a medical professional at a remote location, the patient would be able to communicate with, and transmit diagnostic information to, a medical professional at a monitoring center (MC) or an ER, prior to visiting an ER. The medical professional, being able to communicate with and review a plurality of the patient's diagnostic information, can quickly decide if this patient has an emergency or not, and the medical professional is also in a position to periodically monitor this patient, over a period of several hours. This could be done at a cost which would be a fraction of an ER visit and would free up ER's to care for patients actually requiring emergency treatment.

5. Once we look beyond the urban areas, especially in large central and mid-western states, patients live hundreds of miles away from their doctors. Follow-up of these patients is a problem. Providing transportation to sick people is a lofty idea, but in practice is quite expensive. A means for gathering and transmitting a plurality of diagnostic information to, and for communicating with, a remote location provides the medical community with a formidable, cost-effective tool.

6. A means for gathering and transmitting a plurality of diagnostic information to, and for communicating with, a remote location, in addition to providing a means for preventing unnecessary ER visits, can also be helpful in providing emergency care to patients who, for all practical purposes, cannot get to an ER, such as airplane or boat passengers. The medical professional at a remote location can monitor the patient's diagnostic information and be able to communicate with the patient or persons by the patient's side for the purpose of providing medical instructions to the patient and/or persons.

7. In the prior art, there are devices which gather and transmit diagnostic information (such as EKG) to a remote location. However, these prior art devices are limited in the amount and type of diagnostic information they can gather and transmit. Moreover, these prior art devices are typically complicated and difficult to use. Accordingly, it would be desirable to provide a simple to use means for gathering and transmitting a plurality of diagnostic information and for communicating with a remote location.

8. If a patient were suffering from symptoms consistent with a heart attack, in order to provide an accurate diagnosis and/or course of action, the examining medical professional would preferably gather the following minimum diagnostic information: Electrocardiogram (EKG); Blood Pressure (BP); Pulse; and body temperature. In many instances, a medical professional would also prefer to be able to determine the percentage of oxygen saturation in the blood (%O₂); and auscultation of the patient's heart and lungs. Also, the examining medical professional would prefer to communicate with the patient or person(s) by the patient's side to aid in gathering diagnostic information and/or to provide medical instructions. Accordingly, it would be desirable to provide an inexpensive and easy to use probe device which could gather and transmit to a remote location the above-mentioned diagnostic information and also provide the ability to allow oral communication with a remote location.

DISCLOSURE OF THE INVENTION

9. An object of the present invention is to provide an inexpensive and easy to use probe which could gather and transmit plurality of diagnostic information to a remote location.

10. In carrying out the above object, a system for collecting a plurality of diagnostic information and transmitting the diagnostic information to a remote location is provided. The system comprises a glove member adaptable to be worn on a person's hand and an interface unit in electrical communication with the glove member. The interface unit is capable of transmitting information to, and receiving information from, a remote location. The glove member comprises a palm portion, a wrist portion and five phalange portions. The glove member further comprises an EKG diagnostic device, a blood pressure and pulse rate device and a temperature device. Also, the glove member could have a %O₂ device, as well as an auscultation device.

BRIEF DESCRIPTION OF THE DRAWINGS

11.FIG. 1 is a schematic view of the system of the present invention;

12.FIG. 2 is a plan view of a first side of an apparatus of the present invention;

13.FIG. 3 is a plan view of a second side of an apparatus of the present invention;

14.FIG. 4 is a schematic diagram of the circuit of the interface unit shown in FIG. 1; and

15.FIG. 5 is an exploded view of an EKG sensor used in FIGS. 2 and 3.

BEST MODE FOR CARRYING OUT THE INVENTION

16. The present invention relates to a system, and a diagnostic probe for use with the system, for obtaining a plurality of medical diagnostic information. In particular, the present invention relates to a system, a diagnostic probe device and an information transmission device for use with the system, for gathering cardiac related diagnostic information and transmitting the information to a remote location, such as a medical monitoring command center.

17. As representative of the present invention, FIG. 1, illustrates a system 10 for gathering, and transmitting, to a remote location a plurality of diagnostic information.

18. The system 10 includes a glove probe 12. The glove probe 12 is a unitary member which is adaptable to be worn over a person's hand. The glove probe 12 includes a plurality of medical diagnostic probes which gather diagnostic signals, as will be explained in more detail below. The glove probe 12 is connected via a cable 14 to an interface unit 20 and, thus communicates with, and is capable of transmitting diagnostic signals, or information, from the medical diagnostic probes to the interface unit. The interface unit 20 communicates with a remote command center 22 via a telephone wire or fiber A, a satellite connection B, or a radio wave connection C. The interface unit 20 alternatively communicates with a personal computer (PC) 24 via an interface connection D. The interface unit 20 also communicates with a plurality of local diagnostic readout apparatuses 26 a, 26 b, 26 c, 26 d, and 26 e via an interface connection E via a plurality of interface connections, 28 a, 28 b, 28 c, 28 d, and 28 e, respectively. The diagnostic readout apparatuses 26 a-e are preferably an electrocardiogram (EKG) readout; a blood pressure (BP) and pulse readout, a %O₂ oxygen readout, a temperature readout, and a stethoscope, respectively.

19. Referring to FIG. 2, the glove probe 12 comprises a first glove layer 30 and a second glove layer 32 secured to the first glove layer such that the second glove layer overlies most of the first glove layer. The first glove layer 30 is preferably made of a cloth of natural or synthetic fibers. The second layer 32 is preferably made of a rubber or rubber-like material.

20. The glove probe 12 includes a palm portion 1, a wrist portion 3, a thumb phalange portion 5, an index finger phalange portion 7, a middle finger phalange portion 9, a ring finger phalange portion 11 and a pinky finger phalange portion 13. The glove probe 12 further includes a palmar side 36 (FIG. 2) and a dorsal side 38 (FIG. 3). The palmar side 36 (FIG. 2) includes a palmar palm portion surface 36 a, a palmar wrist portion surface 36 b, a palmar thumb phalange portion surface 36 c, a palmar index finger phalange portion surface 36 d, a palmar middle finger phalange portion surface 36 e, a palmar ring finger phalange portion surface 36 f and a palmar pinky finger phalange portion surface 36 g. The dorsal side 38 (FIG. 3) includes a dorsal palm portion surface 38 a, a dorsal wrist portion surface 38 b, a dorsal thumb phalange portion surface 38 c, a dorsal index finger phalange portion surface 38 d, a dorsal middle finger phalange portion surface 38 e, a dorsal ring finger phalange portion surface 38 f and a dorsal pinky finger phalange portion surface 38 g.

21. As discussed previously, the glove probe 12 contains a plurality of medical diagnostic devices. In the embodiment shown in FIGS. 2 and 3, the glove probe 12 contains an EKG diagnostic device, a blood pressure and pulse rate device 54, a temperature device 64, a %O₂ device 70 and an auscultation device 80.

22. The EKG device is capable of measuring the EKG currents of the heart muscle and preferably includes a plurality of sensors 40 a (FIG. 2), 40 b, 40 c, 40 d, 40 e (FIG. 3), 40 f (FIG. 2) and 40 g (FIG. 3) which are secured to the first layer 30 (FIG. 2) of the glove probe 12. An exemplary sensor 40 c is shown in FIG. 5. Each of the sensors 40 a-40 g includes a stainless-steel screen 41 and an EKG gelly sponge 43 disposed between the screen and, preferably, the first layer 30 (FIG. 5). Sensors 40 a, 40 b, 40 c, 40 d and 40 f (FIG. 2) are provided on the palmer side 36 of the glove probe 12. Sensors 40 e and 40 g (FIG. 3) are provided on the dorsal side 38 of the glove probe 12. Sensors 40 a-40 d, 40 f and 40 g preferably extend through, or are not covered by, the second layer 32 so that they are exposed to the environment. Sensor 40 e faces the palmer side 36 of the glove probe 12.

23. More specifically, sensor 40 a (FIG. 2) is positioned on the tip portion of the palmar pinky finger phalange portion surface 36 e of the glove probe 12. Sensor 40 b is positioned on the left side of the palmar palm portion surface 36 a of the glove probe 12. Sensor 40 c is positioned on the upper portion of the palmar index finger phalange portion surface 36 d of the glove probe 12. Sensor 40 d is positioned on the base portion of the palmar pinky finger phalange portion surface 36 g, between sensor 40 a and sensor 40 b, of the glove probe 12. Sensor 40 e (FIG. 3) is located on the left side of the dorsal wrist portion surface 36 b of the of the glove probe 12. Sensor 40 f (FIG. 2) is positioned on the palmar thumb phalange portion surface 36 c of the glove probe 12. Sensor 40 g (FIG. 3) is positioned on the dorsal palm portion surface 38 a of the glove probe 12.

24. Each of the sensors 40 a-40 g are connected to a wire 42 a-42 g, respectively, which extends between and electrically connects a respective one of the sensors 40 a-40 g with a female connection plug 48, which is preferably provided on the dorsal side of the glove probe 12. Each wire 42 a-42 g is preferably disposed between the first and second layers 30 and 32 of the glove probe 12, and is preferably secured to the first layer 30. Each wire 42 a-42 g is preferably shielded and has a powdered-iron bead 44 c (FIG. 5), such as Part No. T12-41 from Amidon Associates in Santa Ana, Calif. (shown only with respect to sensor 40 c) disposed adjacent to its respective sensors 40 a-40 g to help prevent the detection of unwanted noise.

25. The glove probe 12 includes a ground strip 50 (FIG. 3) which is preferably positioned on the palm portion 3 of the dorsal side 38 between the first and second layers 30 and 32. Each wire 42 a-42 g is connected to the ground strip 50, preferably, via each respective wire shield. The ground strip 50 is connected to a wire 52, which extends between and connects the ground strip 50 to the female connection plug 48. The ground strip 50 functions to bring existing electromagnetic forces (EMF) noise to a single electrical voltage point for removal.

26. The blood pressure device 54, which is capable of measuring systolic and diastolic blood pressure and pulse rate signals, is preferably secured to the first layer 30 of the glove probe 12 between the first layer and the second layer 32 on the wrist portion 3 of the dorsal side 38 of the glove probe. The blood pressure device 54 preferably includes an expandable air bladder 56 defining a chamber for accommodating air or another suitable inflation fluid, an acoustical coupler 58 in the chamber and an air tube 60. The air tube 60 extends between and provides fluid and audio communication between the chamber of the air bladder 56 and the female connection plug 48. The acoustical coupler 58 is capable of collecting the sound waves in the air bladder 56 and directing the sound waves towards, and through, the air tube 60. The blood pressure device 54 is preferably made of parts similar, or identical, to parts of the UB-302 Systolic/Diastolic (Pulse) Digital Blood Pressure monitor from A+D Engineering Inc., of Milpitas, Calif.

27. The temperature device 64 is capable of measuring temperature signals and preferably includes a thermistor 66. The thermistor 66 is preferably positioned on the tip of the middle finger phalange portion 9. The thermistor 66 is preferably secured to the first layer 30 and extends through the second layer 32. The temperature device 64 includes a pair of wires 68 which extend between and electrically connect the thermistor 66 and the female connection plug 48. The temperature device 64 is preferably made of parts similar, or identical, to parts of the Cole-Parmer E-08402-00 thermometer and Generic thermistor E-08459-10 from Cole-Parmer Instrument Company of Vernon Hills, Ill.

28. The %O₂ device 70 is capable of measuring the percent oxygen saturation in the blood (%O₂) signals and preferably includes a red (600-660 nm) and infra-red (880-1000 nm) LED emitter 72 and an LED (600-1000 nm) sensor 74. The LED emitter 72 is preferably secured to the inner surface of the first layer 30 on the palmar side 36 of ring finger phalange portion 11 of the glove probe 12 and the LED sensor 74 is preferably secured to the inner surface on the dorsal surface 38 of the ring finger phalange portion 11 of the glove probe such that the LED emitter faces the LED sensor. The LED emitter 72 is connected to a pair of wires 76 which extend between and electrically connect the LED emitter and the female connection plug 48. The LED sensor 74 is connected to a pair of wires 78 which extend between and electrically connect the LED sensor and the female connection plug 48. The %O₂ device 70 is preferably made of parts similar, or identical, to parts of the Nonin Onyx blood flow and oxygen % reader, model No. 8500M from Nonin Medical, Inc., of Plymouth, Minn.

29. The auscultation device 80 is capable of detecting the sound waves local to the patient's heart and lungs and preferably includes an acoustical coupler and microphone 82, an air tube 84, and a pair of wires 86. The acoustical coupler and microphone 82 is preferably secured to the right side of the palm portion 1 of the palmar side 36 of the glove probe 12, preferably on the first layer 30. The acoustical coupler and microphone 82 is capable of collecting and amplifying sound waves in relative close proximity to the acoustical coupler and microphone. The air tube 84 includes a first end 84 a and a second end 84 b. The first end 84 a of the air tube 84 is preferably connected to the acoustical coupler and microphone 82 and the second end 84 b is adaptable for connection with a stethoscope. The air tube 84, thus when connected to a stethoscope, extends between and provides audio communication between the acoustical coupler and microphone 82 and the stethoscope. The pair of wires 86 extend between and electrically connect the acoustical coupler and microphone 82 and the female plug 48. The auscultation device 80 is preferably made of parts similar, or identical, to parts of the EG Company microphone 9445 from the Electrical Gold Co. Of Scottsdale, Ariz.

30. The glove probe 12 is manufactured by securing, by any suitable means, the wires, sensors, and other components to a glove, preferably made of cloth (i.e., the first layer 30). It should be noted that the wires and/or sensors could be made using flexible circuit technology, such as by using a conductive printable ink. The components of the glove probe 12 which do not extend past the second layer 32 are then covered by the second layer in a suitable manner, such as by spraying or dip coating.

31. The cable 14 includes a first male plug 14 a (FIG. 3), which plugs into male receptors on the female connection plug 48 on the glove probe 12, and a second male plug 14 b (FIG. 4), which plugs into male receptors on a female connection plug 19 on the interface unit 20. The cable 14 (FIG. 1) preferably includes a plurality of electrical wires and air tubes which extend between plugs 14 a and 14 b to provide electrical, audio, and fluid communication between the glove probe 12 and the interface unit 20 when the male plugs 14 a (FIG. 3) and 14 b (FIG. 4) are plugged into their respective female connection plugs 48 (FIG. 3) and 19 (FIG. 4).

32. The interface unit 20 (FIG. 1) preferably includes an EKG circuit board 21 (FIG. 4) for receiving EKG currents detected by the sensors 40 a-40 g, a blood pressure circuit board 23 for receiving systolic and diastolic blood pressure and pulse rate signals from the blood pressure device 54, a temperature circuit board 25 for receiving temperature signals from the temperature device 64 and a %O₂ circuit board for receiving %O₂ signals from the %O₂ device 70. The EKG circuit board 21 is capable of amplifying the EKG currents from the sensors 40 a-40 g and converting the EKG currents to at least a plurality of EKG analog outputs. The blood pressure circuit board 23 is capable of (i) converting the systolic blood pressure signals to a systolic blood pressure analog output, (ii) the diastolic blood pressure signals to a diastolic blood pressure analog output, and (iii) the pulse rate signals to a pulse rate analog output. The blood pressure circuit board 23 includes a source of inflation fluid, such as an air pump 23 a, for supplying a source of inflation fluid for the air bladder 56, and an acoustical sensor (not shown) for detecting the systolic and diastolic blood pressure and pulse rate signals. The pump 23 a is in fluid communication with the air bladder 56 (FIG. 2) via the air tube 60, cable 14 (FIG. 1) and air conduit 17 (FIG. 4), which extends between and provides fluid and audio communication between the female connection plug 19 of the cable 14 and the blood pressure circuit board 23. The temperature circuit board 25 converts the temperature signals to a temperature analog output. The %O₂ circuit board 27 converts the %O₂ signals to a %O₂ analog output. The interface unit 20 also includes an audio amp 29 for amplifying the sound waves received from the auscultation device 80 (FIG. 2).

33. The interface unit 20 further includes a first analog to digital converter 31 for converting the EKG analog outputs to an EKG digital data stream, a second analog to digital converter 33 for converting (i) the systolic blood pressure analog output to a systolic blood pressure digital data stream, (ii) the diastolic blood pressure analog output to a diastolic blood pressure digital data stream, and (iii) the pulse rate analog output to a pulse rate digital data stream, a third analog to digital converter 35 for converting the temperature analog output to a temperature digital data stream, a fourth analog to digital converter 37 for converting the %O₂ analog output to a %O₂ digital data stream, and a fifth analog to digital converter 41 for converting the sound waves from the first audio amp 29 to a sound digital data stream.

34. The interface unit 20 further includes a multiplexer 45 for combining the digital data streams from the analog to digital converters 31-37 and 41 to a combined digital data stream. The combined digital data stream can then be conveyed to the PC 24 via a first port 47, or to the command center 22 (FIG. 1) by satellite connection B via a modem, or by radio wave connection C via the port 47, or to the command center 22 by telephone wire, or fiber, A via telephone modem 51 (FIG. 4) and a second port 53 (FIG. 4). The digital data streams from the interface unit 20 are then converted or interpreted into readable diagnostic information in the command center 22 or the PC 24. This circuitry enables the glove probe 12 and the interface unit 20 to be provided at a reasonable cost. The multiplexer 45 also communicates with a control panel and indicator circuit board 55.

35. The interface unit 20 further includes a speaker/microphone 61 which communicates with the multiplexer 45, via a second audio amp 63 and a sixth analog to digital converter 65, to enable a medical professional in the command center 22 to communicate orally with the persons in relative close proximity to the speaker/microphone.

36. The interface unit 20 includes a third port 71 for receiving and transmitting EKG currents detected by sensors 40 a-40 g to an EKG readout apparatus 26 a (FIG. 1) where the EKG currents will be converted or interpreted into readable diagnostic information. The interface unit 20 further includes a fourth, fifth and sixth port 73, 75 and 77, respectively, for receiving and transmitting the analog outputs from the blood pressure circuit board 23, the temperature circuit board 25 and the %O₂ circuit board 27, respectively, to a blood pressure and pulse readout apparatus 26 b, a temperature readout apparatus 26 c, and a %O₂ readout apparatus 26 d where the analog outputs will be converted or interpreted into readable diagnostic information.

37. The interface unit 20 also includes a power supply 81 which supplies power, via power supply distributor 83, to all of the components of the interface unit. The interface unit 20 also preferably includes a battery pack 85 and a battery charger port 87.

38. The interface unit further includes an optical isolator 89 for electrically isolating the entire interface unit 20 and glove probe 12 from any destructive and damaging currents which might be encountered from external communication links.

39. The manner of operation of the system 10 will now be described. The patient places the glove probe 12 over his or her right hand so that each of the patient's fingers are received within a respective one of the phalange portions 5-13. The glove probe 12 can then preferably be tightened around the patient's wrist by any suitable means such as a velcro strap. The glove probe 12 is then connected to interface unit 20 by cable 14.

EKG Diagnostic Information

40. To obtain EKG diagnostic information, the palmar side 36 of the glove probe 12 is placed over the patient's chest area proximate to the patient's heart. The sensors 40 a-40 g are located at strategic positions on the glove probe 12, as described above, to enable a plurality of leadwire combinations to detect a plurality of standard leads when the glove probe 12 is placed over the patient's left breast. Some exemplary leadwire combinations are as follows:

41. I. Five-Leadwire Scenario:

42. With the glove probe 12 placed in a normal manner over the left breast, it is believed that at least the following leadwires are possible:

43. LL acting leadwire: Sensor 40 a on the tip portion of the pinky finger phalange 13 is positioned under the left breast.

44. RL leadwire: Sensor 40 e on the right wrist.

45. LA acting lead: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

46. RA acting leadwire: Sensor 40 f on the tip portion of the thumb phalange 5 is positioned above and into the right shoulder quadrant.

47. C leadwire: Sensor 40 b on the palm portion is positioned at the right sternal border.

48. With the glove probe 12 positioned in the five leadwire scenario, it is believed that the following lead readings are possible: Lead 1, Lead 2, Lead 3, AVR and AVL.

49. II. Alternate Five-Leadwire Scenario (yields a more dynamic waveform reading):

50. With the glove probe 12 rotated from the normal left breast position of the five leadwire scenario by 10 to 15 degrees toward the right breast and with the patient's free left wrist pressed against the dorsal surface 38 of the glove probe, it is believed that at least the following leadwires are possible:

51. LL leadwire: Sensor 40 g on the dorsal surface 38 of the glove probe 12 is positioned against the patient's left wrist.

52. RL leadwire: Sensor 40 e on the right wrist.

53. LA acting leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

54. RA leadwire: Sensor 40 f on the tip portion of the thumb phalange 5 is positioned above and into the right shoulder quadrant.

55. C leadwire: Sensor 40 b on the palm portion is positioned at the right sternal border.

56. III. Seven-Leadwire Scenario:

57. With the glove probe 12 placed in the normal left breast position of the five leadwire scenario and the patient's left wrist pressed against the dorsal surface 38 of the glove probe, it is believed that at least the following leadwires are possible:

58. LL leadwire: Sensor 40 g on the dorsal surface 38 of the glove probe 12 is positioned against the patient's left wrist.

59. V2 leadwire: Sensor 40 d on the base portion of the pinky finger phalange 13 is positioned in the V2 position.

60. V4 leadwire: Sensor 40 a on the tip portion of the pinky finger phalange 13 is positioned in the V4 position.

61. RL leadwire: Sensor 40 e on the right wrist.

62. LA acting leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

63. RA leadwire: Sensor 40 f on the tip portion of the thumb phalange 5 is positioned above and into the right shoulder quadrant.

64. C leadwire: Sensor 40 b on the palm portion is positioned at the right sternal border.

65. With the glove probe 12 positioned in the seven leadwire scenario, it is believed that at least the following lead readings are possible: Lead 1, Lead 2, Lead 3, AVR, AVL, V2 and V4.

66. IV. Three-Leadwire Scenarios:

67. It is believed that the following leadwires are also possible:

68. Lead 1:

69. Positive leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

70. Negative leadwire: Sensor 40 f on the tip portion of the thumb phalange 5 is positioned above and into the right shoulder quadrant.

71. Ground leadwire: Sensor 40 e on the right wrist.

72. Lead 2:

73. Positive leadwire: Sensor 40 a on the tip portion of the pinky finger phalange 13 is positioned under the left breast towards the V6 position.

74. Negative leadwire: Sensor 40 f on the tip portion of the thumb phalange 5 is positioned above and into the right shoulder quadrant.

75. Ground leadwire: Sensor 40 e on the right wrist.

76. Optional Lead 2:

77. Positive leadwire: Sensor 40 g on the dorsal surface 38 of the glove probe 12 is positioned against the patient's left wrist.

78. Negative leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

79. Ground leadwire: Sensor 40 e on the right wrist.

80. Lead 3:

81. Positive leadwire: Sensor 40 a on the tip portion of the pinky finger phalange 13 is positioned under the left breast towards the V6 position.

82. Negative leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

83. Ground leadwire: Sensor 40 e on the right wrist.

84. Optional Lead 3:

85. Positive leadwire: Sensor 40 g on the dorsal surface 38 of the glove probe 12 is positioned against the patient's left wrist.

86. Negative leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

87. Ground leadwire: Sensor 40 e on the right wrist.

88. MCL1 Lead:

89. Negative leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

90. Positive leadwire: Sensor 40 b on the palm portion is positioned at the right sternal border.

91. Ground leadwire: Sensor 40 e on the right wrist.

92. MCL4 Lead:

93. Negative leadwire: Sensor 40 c on the tip portion of the index finger phalange 7 is positioned above the left breast at the left shoulder quadrant.

94. Positive leadwire: Sensor 40 a on the tip portion of the pinky finger phalange 13 is positioned in the V4 position.

95. Ground leadwire: Sensor 40 e on the right wrist.

96. It should be noted that other EKG scenarios can be accomplished at the discretion of the command center 22. Such options are available since the following glove member positions relate to electrical heart activity as below:

97. G (ground) leadwire: Right wrist (sensor 40 e)

98. + (positive) leadwire: left wrist (sensor 40 g)

99. − or + leadwire: Index finger phalange 7 tip (sensor 40 c)

100. − (negative) leadwire: Thumb phalange 5 tip (sensor 40 f)

101. It should also be noted that, in the event that distortion of the EKG waveform occur due to misplacement of the glove EKG sensors 40 a-g, correction of such can be accomplished using waveform modification circuits located at the command center 22. Such waveform modification circuitry accomplishes distortion correction utilizing waveshaping techniques which filter, compare, and re-shape into readable data.

102. The EKG currents, or leads, detected from the sensors 40 a-40 g are transmitted to the female connection plug 48, and through the cable 14 to the interface unit 20 where they can be sent to the command center 22 or PC 24 in a digital data stream, or to the EKG readout apparatus 26 a, as discussed above.

Blood Pressure and Pulse Rate Diagnostic Information

103. To obtain blood pressure and pulse rate diagnostic information, when the glove probe 12 wrist portion 3 is tightened around the patient's wrist, the air bladder 56 is ready to accept air pressure from the pump 23 a in the blood pressure circuit board 23. The air pump 23 a then transmits inflation fluid, such as air, via the conduit 17, cable 14 and air tube 60, to the air bladder 56 to inflate the air bladder. Inflation of the air bladder 56 obliterates the radial artery. As the air bladder 56 releases the inflation fluid, pulse sound waves are acoustically picked-up by acoustical coupler 58 and are sent over the air tube 60 to the female connection plug 48, and through the cable 14 to the interface unit 20 where they can be sent to the command center 22 or PC 24 in a digital data stream, or to the blood pressure and pulse rate readout 26 b, as discussed above.

Body Temperature Diagnostic Information

104. To obtain body temperature diagnostic information, the middle finger phalange portion 9 of the glove probe 12 is placed under the patient's tongue for a period of time sufficient to receive temperature signals from the thermistor 66, preferably about one minute. The temperature signals from the temperature device 64 can be transmitted to the female connection plug 48, and through the cable 14 to the interface unit 20 where they can be sent to the command center 22 or PC 24 in a digital data stream, or to the temperature readout apparatus 26 c, as discussed above.

%O₂ Diagnostic Information

105. To obtain %O₂ diagnostic information, the red LED emitter 72 (FIG. 2) emits red and infra-red light toward the LED sensor 74. When the light from the LED emitter 72 is passed through the patient's finger (non-painted finger nails only) at the nail, the LED sensor 74 detects the color light waves present. These signals are translated from light intensity and color quality to oxygen levels. More oxygen yields a light red blood while less oxygen produces a darker red to purple blood. It should be noted that pulse rate can also be ascertained from these readings.

106. The %O₂ signals from the %O₂ device 70 are then sent to the female connection plug 48, and through the cable 14 to the interface unit 20 where the %O₂ signals can be sent to the command center 22 or PC 24 in a digital data stream, or to the %O₂ readout apparatus 26 d, as discussed above.

Auscultation Diagnostic Information

107. To listen to the heart and lungs of the patient, the glove probe 12 is moved over the patient's body to enable the acoustical coupler and microphone 82 to pick up, or hear, sound waves from the patient's heart and lungs, much like a stethoscope would. The sound waves are then transmitted to the female connection plug 48, via the pair of wires 86, and then through the cable 14 to the interface unit 20, where they can be sent to the command center or PC 24, in a digital data stream as described above. Alternatively, the sound waves from the acoustical coupler of the acoustical coupler and microphone 82 could also be conducted via air tube 84 to a stethoscope 26 e, as described above.

Oral Communication

108. To communicate orally with a remote location, such as the command center 22, the speaker/microphone 61 can transmit and receive sound waves as described above. It should be noted that the interface unit 20 may not be able to transmit or receive sound waves via speaker/microphone 61 when processing diagnostic information from the EKG diagnostic device, the blood pressure device 54, the temperature device 64, the %O₂ device 70 and/or the auscultation device 80.

109. While the best modes for carrying out the invention have been described in detail, those familiar with the art to which the invention relates will appreciate other ways of carrying out the invention defined by the following claims. For instance, the placement of the diagnostic devices on the glove probe 12 and/or specific design of the diagnostic devices could vary from that described above. For instance, the EKG device could have more or fewer sensors or the sensors could be located differently than that described above. Moreover, the glove probe could be adapted to be worn on the patient's left hand. 

What is claimed is:
 1. A system for collecting a plurality of diagnostic information and transmitting the diagnostic information to a remote location, said system comprising; a member adaptable to be worn on a person's hand, said member comprising a plurality of diagnostic devices, said diagnostic devices capable sensing diagnostic signals from a person; and an interface unit in electrical communication with said member, said interface unit capable of transmitting information to, and receiving information from, a remote location.
 2. The system of claim 1 wherein said plurality of diagnostic devices includes an EKG diagnostic device, a blood pressure and pulse diagnostic device and a temperature device.
 3. The system of claim 2 wherein said plurality of diagnostic devices further includes a %O₂ diagnostic device.
 4. The system of claim 3 wherein said plurality of diagnostic devices further includes a auscultation device.
 5. The system of claim 4 further comprising a satellite modem, wherein the remote location comprises a command center and said interface units transmits information to, and receives information from, the remote location via a satellite connection through said satellite modem.
 6. The system of claim 4 further comprising a telephone modem, wherein the remote location comprises a command center and said interface units transmits information to, and receives information from, the remote location via a telephone wire connection through said telephone modem.
 7. The system of claim 4 wherein said remote location comprises a personal computer.
 8. The system of claim 4 wherein said remote location comprises a plurality of diagnostic readout machines.
 9. The system of claim 4 wherein said member comprises a palm portion, a wrist portion and five phalange portions.
 10. The system of claim 9 wherein said EKG diagnostic device includes at least a first EKG sensor located on said palm portion, a second EKG sensor located on said wrist portion, and a third EKG sensor located on at least one of said phalange portions.
 11. The system of claim 10 wherein said EKG diagnostic device includes at least seven EKG sensors.
 12. The system of claim 9 wherein said blood pressure and pulse rate device is located on said wrist portion of said member and includes an inflatable air bladder.
 13. The system of claim 12 wherein said temperature device includes a thermistor which is responsive to temperature changes.
 14. The system of claim 13 wherein said %O₂ device includes a LED emitter and an LED sensor, said led sensor and led emitter being located on one of said phalange portions.
 15. The system of claim 14 wherein said interface unit comprises an EKG circuit board, a blood pressure and pulse rate circuit board, a temperature board, a %O₂ circuit board, wherein said blood pressure and pulse rate circuit board includes a source of inflation fluid for inflating said air bladder.
 16. A diagnostic probe comprising: a glove member comprising a palm portion, a wrist portion and five phalange portions, said glove member adaptable to be worn on a person's hand; an EKG diagnostic device located on said glove member; a blood pressure and pulse rate device located on said glove member; and a temperature device located on said glove member.
 17. The diagnostic probe of claim 16 further comprising a %O₂ device located on said glove member and an auscultation device.
 18. The diagnostic probe of claim 17 further comprising an electrical connection plug capable of communicating with said devices and an information transmission device, said probe further comprising electrical circuitry providing electrical communication between said devices and said plug.
 19. The diagnostic probe of claim 18 wherein said EKG diagnostic device includes at least a first EKG sensor located on said palm portion, a second EKG sensor located on said wrist portion, and a third EKG sensor located on at least one of said phalange portions, said blood pressure and pulse rate device being located on said wrist portion of said member and including an inflatable air bladder, said temperature device including a thermistor which is responsive to temperature changes, and said %O₂ device including a LED emitter and an LED sensor, said led sensor and led emitter being located on one of said phalange portions.
 20. The probe of claim 19 wherein said auscultation device includes an acoustical coupler and microphone.
 21. The probe of claim 19 wherein each of said EKG sensors includes a stainless steel screen and a sponge for supplying an electrical contact enhancing fluid, said sponge being disposed between said glove member and said screen. 